Interaction effect of process parameters and
            <scp>Pd‐electrocatalyst</scp>
            in formic acid
            <scp>electro‐oxidation</scp>
            for fuel cell applications: Implementing supervised machine learning algorithms

Hossain, SK Safdar; Ali, Syed Sadiq; Rushd, Sayeed; Ayodele, Bamidele Victor; Cheng, Chin Kui

doi:10.1002/er.7602

Cited by 9 publications

(3 citation statements)

References 50 publications

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“…Delamination wear causes thin laminates to discard as waste due to the instability of crack propagation at the tribosurface's subsurface. Exfoliation, craters, and scratches are far less common on AA7075graphene nanocomposites than on base AA7075, according to research by Li et al [27] and Hossain et al [28].…”

Section: Mechanisms Of Wear and Friction In Aa7075-graphene Nanocompo...mentioning

confidence: 99%

Study of Friction and Wear Behavior of Graphene-Reinforced AA7075 Nanocomposites by Machine Learning

Prasanth

Jeevanandam²,

Selvaraju³

et al. 2023

Journal of Nanomaterials

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In this research, the friction and wear of AA7075 nanocomposites reinforced with graphene and graphite were studied. Graphene’s inclusion dramatically enhanced the material’s mechanical characteristics, friction, and wear resistance. AA7075 is strengthened with less graphene, and AA7075, reinforced with more graphite, exhibits similar wear and friction behavior. Wear rate and coefficient of friction predictions for AA7075-graphene nanocomposites were made using five machine learning (ML) regression models. ML simulations reveal that the wear and friction of AA7075-graphene composites are most sensitive to the proportion of graphene presence, the loadings, and the hardness.

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Section: Mechanisms Of Wear and Friction In Aa7075-graphene Nanocompo...mentioning

confidence: 99%

Study of Friction and Wear Behavior of Graphene-Reinforced AA7075 Nanocomposites by Machine Learning

Prasanth

Jeevanandam²,

Selvaraju³

et al. 2023

Journal of Nanomaterials

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“…Many current findings have offered machine learning-based fuel cell modeling methods. Hossain et al [6] have proposed a machine learning algorithm namely Support Vector Machine (SVM) regression, Regression Trees, and Gaussian Process Regression (GPR) for modeling the effect of palladium supported on carbon nanotube used for formic acid electro-oxidation for DBFC. In previous research, we also have developed an artificial neural network-based fuel cell design approach for proton exchange membranes, the most prevalent and commonly used fuel cell type [7].…”

Section: Related Workmentioning

confidence: 99%

Machine Learning-Based Current Density Simulation for Direct Borohydride Fuel Cell

Mohamed

Ibrahem

Lee

et al. 2022

Machine Learning and Artificial Intelligence

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Recent studies on fuel cell design have showed that the use of simulation tools is beneficial in terms of saving time and money. Current density management is still a key research problem for several technologies, including Direct Borohydride Fuel Cell (DBFC). This paper describes a systematic machine learning technique for estimating the cell current density for DBFC as a function of various input factors. Artificial Neural Networks (ANN) and Decision Tree Regressor (DTR) are two popular machine learning models that were trained and evaluated for the current density simulation using a conducted fuel cell experiments presented in previous research. The ANN model performed the better than the DTR model in the simulation, with a mean absolute error of 3.00015 for training and 5.57614 for testing. The simulation exhibits very small error values, indicating that the suggested approaches accurately mirror real-world DBFC process.

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“…The bioethanol production is most favorable at 240 h, pH of 9, the temperature of 300 K, and yeast extract of 4500 mg/L. The application of machine learning algorithms such as GPR can harness the enormous potential of renewable energy [34]. The renewable energy industry would be left behind were GPR not adopted for the full transition process.…”

Section: Input Parameters Importance Analysis and Study Implicationsmentioning

confidence: 99%

Predictive Modeling of Bioenergy Production from Fountain Grass Using Gaussian Process Regression: Effect of Kernel Functions

2022

Self Cite

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Experimental studies have shown that bioethanol production from biomass sources has been reported to be influenced by several process parameters. It is not entirely known, however, how the interaction of these factors affects the concentration of bioethanol production. In this study, the use of Gaussian Process Regression (GPR) in predictive modeling of bioethanol production from fountain grass has been investigated. Parametric analysis showing the interaction effect of time, pH, temperature, and yeast extract on the bioethanol production was examined. The effect of kernel functions on the performance of the GPR in modeling the prediction of bioenergy output was also examined. The study shows that the kernel function, namely, rotational quadratic (RQGPR), squared exponential (SEGPR), Matern 5/2 (MGPR), exponential (EGPR), and the optimizable (Opt.GPR.), had varying effects on the performance of the GPR. Coefficients of determination (R2) of 0.648, 0.670, 0.667, 0.762, and 0.993 were obtained for the RQGPR, SEGPR, MGPR, EGPR, OptGPR, respectively. The OptGPR with R2 of 0.993 and RMSE of 45.13 displayed the best performance. The input parameters analysis revealed that the pH of the fermentation medium significantly influences bioethanol production. A proper understanding of how the various process variables affect bioethanol production will help in the real-time optimization of the process in the eventuality of scale-up.

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Interaction effect of process parameters and Pd‐electrocatalyst in formic acid electro‐oxidation for fuel cell applications: Implementing supervised machine learning algorithms

Cited by 9 publications

References 50 publications

Study of Friction and Wear Behavior of Graphene-Reinforced AA7075 Nanocomposites by Machine Learning

Study of Friction and Wear Behavior of Graphene-Reinforced AA7075 Nanocomposites by Machine Learning

Machine Learning-Based Current Density Simulation for Direct Borohydride Fuel Cell

Predictive Modeling of Bioenergy Production from Fountain Grass Using Gaussian Process Regression: Effect of Kernel Functions

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